A profile production blanking mechanism
By designing an adjustable-angle feed hopper and a quick-connect receiving box, the problem of low profile collection efficiency in existing aluminum profile forming and feeding mechanisms has been solved, achieving stable and efficient profile collection and improving the working environment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WUXI QIANCHEN TECH CO LTD
- Filing Date
- 2025-08-06
- Publication Date
- 2026-06-05
AI Technical Summary
The existing aluminum profile forming and unloading mechanism does not have an adjustable unloading hopper structure and a quick-connect receiving box, resulting in low profile collection efficiency and easy blockage, which affects the operating efficiency of the staff.
A profile production unloading mechanism was designed, comprising a support, a cutting device, a receiving box, an unloading hopper, and an adjustment structure. The receiving box and the support are quickly connected by plug-in and magnetic connection. Universal wheels and magnetic iron plates are set to improve movement stability. The angle of the unloading hopper can be adjusted to adapt to the needs of different profiles, and dust removal holes are set on the outer surface of the unloading hopper to discharge waste materials.
It enables the adjustment of the hopper angle and the quick connection of the receiving box, improving the efficiency of profile collection, reducing profile damage and waste accumulation, improving the working environment, and increasing the operational efficiency of the staff.
Smart Images

Figure CN224324683U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of aluminum profile processing technology, specifically a profile production blanking mechanism. Background Technology
[0002] Aluminum profiles are profiles with specific cross-sectional shapes and dimensions, made primarily of aluminum through processes such as hot melting and extrusion. Due to their excellent comprehensive performance, they are widely used in numerous fields. In the construction industry, aluminum profiles are commonly used to make doors, windows, curtain walls, and partitions, offering not only aesthetic appeal but also good sealing and thermal insulation. In the transportation industry, automobiles, trains, and ships extensively utilize aluminum profiles to reduce weight and energy consumption. In the industrial sector, aluminum profiles can be used to manufacture frames, supports, and guide rails for various mechanical equipment. In the electronics and electrical appliance industry, aluminum profiles are frequently used as components such as heat sinks and housings. During the production and processing of aluminum profiles, material preparation is one of the key steps in their production.
[0003] Chinese Utility Model Patent Publication No. CN 219949673 U discloses an aluminum profile forming and unloading mechanism. The specification of this mechanism states that by using a base plate, a fixed plate, a transmission rod, a first gear, a transmission belt, a partition, a limiting shell, an adjusting component, and a sliding groove, it solves the problems of existing unloading mechanisms using conveyor belts, which easily lead to untimely collection by workers, blockages, and reduced stacking efficiency. However, this aluminum profile forming and unloading mechanism lacks an adjustable structure for the unloading hopper, making it inconvenient for workers to control the efficiency of profile collection by adjusting the tilt angle of the hopper. Furthermore, it lacks a quick-connect structure for the receiving box, making it difficult to collect the finished profiles, resulting in poor practicality. Summary of the Invention
[0004] The technical problem to be solved by this utility model is to provide a profile production material feeding mechanism, which can effectively solve the problems in the prior art.
[0005] The technical solution adopted by this utility model is as follows: a profile production material feeding mechanism, including a bracket and a cutting device and a receiving box located in front of the bracket. The cutting device is symmetrically equipped with a fixing plate at one end near the receiving box. A feeding hopper is provided between the two sets of fixing plates. The feeding hopper has through holes and adjustment holes at both ends near the fixing plates. Dust removal holes are provided on the outer surface of the feeding hopper. A rotating shaft is fixedly installed at one end of the fixing plate near the adjustment hole. A limit post is fixedly installed at one end of the fixing plate near the adjustment hole. A locking bolt is threaded to the side of the limit post away from the fixing plate. A positioning groove is provided at one end of the bracket near the receiving box.
[0006] Preferably, a support foot is fixedly installed at the end of the bracket away from the cutting device, a handle is fixedly installed on the side of the receiving box away from the bracket, casters are fixedly installed at the bottom of the receiving box, an insert is fixedly installed at the end of the receiving box near the bracket, a magnetic iron sheet one is fixedly installed at the center of the end of the positioning groove near the receiving box, and a magnetic iron sheet two is fixedly installed at the center of the end of the insert away from the receiving box.
[0007] The above technical solution improves the stability of the support frame by setting support feet, preventing it from tilting due to uneven force. The handle facilitates pushing and pulling of the receiving box by the staff, and the casters enable displacement of the receiving box, allowing staff to move it easily and improving work efficiency.
[0008] Preferably, the cross-section of the insert block is adapted to the cross-section of the positioning groove, and the insert block and the positioning groove are installed by insertion.
[0009] The above technical solution, by setting the insert and positioning groove for plug-in installation, facilitates the quick connection between the receiving box and the bracket. The connection between the receiving box and the bracket improves the stability of the receiving box, prevents deviation during the receiving process, and ensures that the profiles can fall accurately into the receiving box.
[0010] Preferably, the magnetic iron sheet one and the magnetic iron sheet two are magnetically connected.
[0011] The above technical solution, through the design of magnetic iron sheet one and magnetic iron sheet two being magnetically connected, strengthens the connection between the receiving box and the bracket after they are plugged in and installed, ensuring the stability of the receiving box and the bracket after installation. At the same time, the design of magnetic iron sheet one and magnetic iron sheet two being magnetically connected also facilitates the quick disassembly of the receiving box and the bracket, thereby improving work efficiency.
[0012] Preferably, the casters are provided in four identical sets, and the four sets of casters are symmetrically distributed at the bottom center line of the receiving box.
[0013] The above technical solution, by setting four sets of identical casters, facilitates the stability of the receiving box when moving. At the same time, the casters have a self-locking structure, making them highly practical.
[0014] Preferably, the receiving box is located directly below the feeding hopper, and the outer surface of the feeding hopper has multiple sets of dust removal holes at equal intervals.
[0015] By using the above technical solution, and by setting the receiving box directly below the feeding hopper, it is easy for the profiles to fall accurately from the feeding hopper into the receiving box, reducing the need for workers to manually pick up profiles that have fallen outside the receiving box, thus improving work efficiency. Furthermore, by setting multiple sets of dust removal holes at equal intervals on the outer surface of the feeding hopper, waste generated during profile cutting can be discharged in a timely manner, improving the working environment, reducing the harm of waste to operators, and preventing excessive waste from accumulating in the feeding hopper and affecting the feeding process.
[0016] Preferably, the through hole and the rotating shaft are rotatably connected, and the limiting post and the adjusting hole are slidably connected.
[0017] The above technical solution, through the design of the through hole and the rotating shaft being rotatably connected, allows for the adjustment of the angle of the hopper. In addition, the design of the limit post and the adjustment hole being slidably connected allows for the adjustment of the angle of the hopper within the range of the adjustment hole, which facilitates the improvement of the hopper's feeding efficiency.
[0018] Compared with the prior art, this utility model provides a profile production blanking mechanism, which has the following beneficial effects:
[0019] 1. The material feeding mechanism for this profile production uses a design where the through hole and the rotating shaft are rotatably connected, allowing the feeding hopper to rotate flexibly around the shaft. Combined with the design where the limiting post and the adjusting hole are slidably connected, the feeding hopper can guide and limit the movement during rotation. When it is necessary to adjust the tilt angle of the feeding hopper, simply loosen the locking bolt, rotate the feeding hopper, and the limiting post will slide along the adjusting hole. At the same time, the feeding hopper will rotate around the rotating shaft. After adjusting to the required angle, simply tighten the locking bolt to quickly fix the feeding hopper to the fixing plate. This mechanism can quickly adapt to the feeding requirements of different aluminum profiles and avoid profile damage or accumulation caused by fixed angles.
[0020] 2. The material feeding mechanism for this profile production uses a plug-in design with insert blocks and positioning slots for quick connection between the receiving box and the support. Furthermore, the magnetic connection between magnetic iron plates one and two enhances the connection strength between the receiving box and the support, ensuring stability after installation. Simultaneously, the magnetic connection between magnetic iron plates one and two also facilitates quick disassembly of the receiving box and the support, thereby improving work efficiency. Attached Figure Description
[0021] Figure 1 This is a schematic diagram of the three-dimensional structure of the present invention. Figure 1 ;
[0022] Figure 2 This is a schematic diagram of the three-dimensional structure of the present invention. Figure 2 ;
[0023] Figure 3This is a schematic diagram of the installation structure of the feeding hopper of this utility model;
[0024] Figure 4 This is a schematic diagram of the connection structure between the receiving box and the support frame of this utility model;
[0025] Figure 5 This is a three-dimensional structural diagram of the receiving box of this utility model;
[0026] Figure 6 This is a schematic diagram of the installation structure of the feeding hopper and the fixing plate of this utility model;
[0027] Figure 7 This is a schematic diagram showing the disassembled structure of the hopper and the fixing plate of this utility model;
[0028] Figure 8 This utility model Figure 4 A magnified structural diagram of point A in the middle.
[0029] The components include: 1. bracket; 2. support foot; 3. cutting device; 4. fixing plate; 5. hopper; 6. through hole; 7. adjusting hole; 8. dust removal hole; 9. rotating shaft; 10. limiting post; 11. locking bolt; 12. positioning groove; 13. magnetic iron sheet one; 14. receiving box; 15. handle; 16. caster wheel; 17. insert block; 18. magnetic iron sheet two. Detailed Implementation
[0030] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0031] Example 1: As Figure 1-8 As shown, the present invention provides a profile production feeding mechanism, including a support 1, a cutting device 3, and a receiving box 14 located in front of the support 1. A fixing plate 4 is symmetrically installed on one end of the cutting device 3 near the receiving box 14. A feeding hopper 5 is provided between the two sets of fixing plates 4. Through holes 6 and adjustment holes 7 are opened at both ends of the feeding hopper 5 near the fixing plates 4. Dust removal holes 8 are opened on the outer surface of the feeding hopper 5. A rotating shaft 9 is fixedly installed on one end of the fixing plate 4 near the adjustment hole 7. A limiting post 10 is fixedly installed on one end of the fixing plate 4 near the adjustment hole 7. A locking bolt 11 is threadedly connected to the side of the limiting post 10 away from the fixing plate 4. A positioning groove 12 is opened on one end of the support 1 near the receiving box 14.
[0032] Specifically, a support foot 2 is fixedly installed at the end of the bracket 1 away from the cutting device 3; a handle 15 is fixedly installed on the side of the receiving box 14 away from the bracket 1; casters 16 are fixedly installed at the bottom of the receiving box 14; an insert block 17 is fixedly installed at the end of the receiving box 14 near the bracket 1; a magnetic iron sheet 13 is fixedly installed in the center of the positioning groove 12 near the receiving box 14; and a magnetic iron sheet 28 is fixedly installed in the center of the insert block 17 away from the receiving box 14. The advantages are that the support foot 2 improves the stability of the bracket 1, preventing it from tilting due to uneven force; the handle 15 facilitates pushing and pulling the receiving box 14; and the casters 16 enable the displacement of the receiving box 14, allowing for easy movement and improving work efficiency.
[0033] Specifically, the cross-section of the insert 17 matches the cross-section of the positioning groove 12, and the insert 17 and the positioning groove 12 are plug-in installed. The advantage is that by setting the insert 17 and the positioning groove 12 to be plug-in installed, it is easy to quickly connect the receiving box 14 and the bracket 1. Through the connection between the receiving box 14 and the bracket 1, the stability of the receiving box 14 is improved, preventing displacement during the receiving process and ensuring that the profile can accurately fall into the receiving box 14.
[0034] Specifically, magnetic iron sheet 13 and magnetic iron sheet 18 are magnetically connected. The advantage is that this magnetic connection strengthens the connection between the receiving box 14 and the support 1 after they are plugged in, ensuring stability after installation. Furthermore, the magnetic connection also facilitates quick disassembly of the receiving box 14 and the support 1, thus improving work efficiency.
[0035] Example 2: Figure 2-8 As shown, this is an improvement on the previous embodiment.
[0036] Specifically, four identical sets of casters 16 are provided, symmetrically distributed along the bottom centerline of the receiving box 14. The advantage is that by providing four identical sets of casters 16, the stability of the receiving box 14 during movement is improved, and the casters 16 also have a self-locking structure, making them highly practical.
[0037] Specifically, the receiving box 14 is located directly below the feeding hopper 5, and multiple sets of dust removal holes 8 are evenly spaced on the outer surface of the feeding hopper 5. The advantages are that by positioning the receiving box 14 directly below the feeding hopper 5, it facilitates the precise falling of profiles from the feeding hopper 5 into the receiving box 14, reducing the need for manual picking up profiles that fall outside the receiving box 14 and improving work efficiency. Furthermore, by setting multiple sets of dust removal holes 8 at equal intervals on the outer surface of the feeding hopper 5, waste generated during profile cutting can be discharged promptly, improving the working environment, reducing the harm of waste to operators, and preventing excessive waste accumulation in the feeding hopper 5 from affecting material feeding.
[0038] Specifically, the through hole 6 is rotatably connected to the rotating shaft 9, and the limiting post 10 is slidably connected to the adjusting hole 7. The advantage is that the rotatable connection between the through hole 6 and the rotating shaft 9 allows for angle adjustment of the hopper 5. Combined with the slidable connection between the limiting post 10 and the adjusting hole 7, the hopper 5 can be adjusted within the range of the adjusting hole 7, thus improving the feeding efficiency of the hopper 5.
[0039] Working Principle: During use, the design of the insert block 17 and positioning groove 12 for plug-in installation facilitates quick connection between the receiving box 14 and the bracket 1. The magnetic connection between magnetic iron sheet 13 and magnetic iron sheet 18 enhances the connection strength between the receiving box 14 and the bracket 1, ensuring stability after installation. Simultaneously, the magnetic connection between magnetic iron sheet 13 and magnetic iron sheet 18 also facilitates quick disassembly of the receiving box 14 and the bracket 1, thus improving work efficiency. After cutting, the profile enters the feeding hopper 5. The through hole 6 and rotating shaft 9 form a rotatable connection, allowing the feeding hopper 5 to rotate flexibly around the shaft 9. The limiting post 10 and adjusting hole 7 form a sliding connection, guiding and limiting the feeding hopper 5 during rotation. To adjust the tilt angle of the feeding hopper 5, simply loosen the locking bolt 11 and rotate the feeding hopper 5. The positioning column 10 slides along the adjustment hole 7, while the hopper 5 rotates around the rotating shaft 9. After adjusting to the required angle, simply tightening the locking bolt 11 will quickly fix the hopper 5 to the fixing plate 4. By setting the receiving box 14 directly below the hopper 5, the profiles can fall accurately from the hopper 5 into the receiving box 14, reducing the need for workers to manually pick up profiles that fall outside the receiving box 14 and improving work efficiency. By setting multiple sets of dust removal holes 8 at equal intervals on the outer surface of the hopper 5, waste generated during profile cutting can be discharged in time, improving the working environment and reducing the harm of waste to operators. At the same time, it avoids excessive waste accumulation in the hopper 5, which affects the material feeding. By setting universal wheels 16, the receiving box 14 can be moved, making it easy for workers to move the receiving box 14. By setting four sets of identical universal wheels 16, the stability of the receiving box 14 during movement is improved, making it easier for workers to transfer the collected profiles, thereby improving work efficiency.
[0040] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A profile production material feeding mechanism, comprising a support (1), a cutting device (3), and a receiving box (14) located in front of the support (1), characterized in that: The cutting device (3) is symmetrically equipped with a fixing plate (4) at one end near the receiving box (14). A feeding hopper (5) is provided between the two sets of fixing plates (4). The feeding hopper (5) is provided with a through hole (6) and an adjustment hole (7) at both ends near the fixing plate (4). A dust removal hole (8) is provided on the outer surface of the feeding hopper (5). A rotating shaft (9) is fixedly installed at one end of the fixing plate (4) near the adjustment hole (7). A limit post (10) is fixedly installed at one end of the fixing plate (4) near the adjustment hole (7). A locking bolt (11) is threaded on the side of the limit post (10) away from the fixing plate (4). A positioning groove (12) is provided at one end of the bracket (1) near the receiving box (14).
2. The profile production blanking mechanism according to claim 1, characterized in that: The support (1) is fixedly equipped with a support foot (2) at the end away from the cutting device (3). The receiving box (14) is fixedly equipped with a handle (15) on the side away from the support (1). The bottom of the receiving box (14) is fixedly equipped with a caster wheel (16). The receiving box (14) is fixedly equipped with an insert block (17) at the end near the support (1). The positioning groove (12) is fixedly equipped with a magnetic iron sheet one (13) at the center of the end near the receiving box (14). The insert block (17) is fixedly equipped with a magnetic iron sheet two (18) at the center of the end away from the receiving box (14).
3. The profile production blanking mechanism according to claim 2, characterized in that: The cross section of the insert (17) is adapted to the cross section of the positioning groove (12), and the insert (17) and the positioning groove (12) are installed by insertion.
4. The profile production blanking mechanism according to claim 2, characterized in that: The magnetic iron sheet one (13) and the magnetic iron sheet two (18) are magnetically connected.
5. The profile production blanking mechanism according to claim 2, characterized in that: The universal wheels (16) are provided in four identical sets, and the four sets of universal wheels (16) are symmetrically distributed at the bottom center line of the receiving box (14).
6. The profile production blanking mechanism according to claim 1, characterized in that: The receiving box (14) is located directly below the feeding hopper (5), and the outer surface of the feeding hopper (5) has multiple sets of dust removal holes (8) at equal intervals.
7. The profile production blanking mechanism according to claim 1, characterized in that: The through hole (6) is rotatably connected to the rotating shaft (9), and the limiting post (10) is slidably connected to the adjusting hole (7).